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Digital Camera System for Recording, Editing and Visualizing Images

a digital cinema and camera system technology, applied in the field of digital cinema camera systems, can solve the problems of inability to manage the network, the complexity of the design of the digital cinema camera, and the inability to fully manage the network, so as to achieve the effect of reducing the data rate, improving the throughput and reducing the complexity of the design

Active Publication Date: 2010-05-06
SILICON IMAGING CORP
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Benefits of technology

[0010]This invention enables reduced complexity for capturing imagery from one or more image modules, enables remote image sensing and frame grabbing with transmission using existing industry standard broadcast and networking infrastructure, improves storage and processing efficiency, provides increased flexibility and tools visualization, networking, analysis and mixing of prerecorded or computer generated data, and delivers unique display modes 2D and 3D representation of the multiple streams during live, recording, playback or post processing. The disclosed digital camera system may include optics, one or more imaging modules, a frame grabber, a processor, software, user input mechanism, a display, synchronization mechanism, networking means and storage means. In addition, a configuration is disclosed for a portable digital camera and recording system capable of HD, 2K and 4K stereo-3D or wide-dynamic multi-image acquisition using two image sensing modules and separated image processing, recording and display subsystem.

Problems solved by technology

In the past few years, while several digital cinema cameras have emerged on the market these digital cinema cameras are complex designs with limited connectivity that are only able to address a limited set of the needs described above.
For example, these digital cinema cameras are incompatible with existing cable infrastructure.
Also, these digital cinema cameras either completely lack network management or are capable of only minimal network management (i.e., only simple controls that lack full image streaming or metadata management).
Further, these digital cinema cameras lack the ability to capture or record multi-sensor 2K or 4K image data using a single control application.
Additionally, these digital cinema cameras lack visualization tools or metadata integration.
These digital cinema cameras do not utilize existing broadcast infrastructure to transmit multi-resolution data and have complex workflows with respect to stereo 3D and multi-camera content acquisition, broadcast and network transmission either live or in a post production process.
These digital cinema cameras are limited to 1920×1080 image sensor pixel arrays that require the use of a multiple sensor prism block which, in turn, requires use of complex and expensive optics.
These digital cinema cameras utilize dedicated hardware functions with no or limited image processing flexibility or upgrade capability.
While a number of these digital cinema cameras can generate preview imagery for display on an electronic viewfinder, these digital cinema cameras can only do so with limited resolution or visualization tools.
These digital cinema cameras often output imagery to be record on restrictive, proprietary or large external storage devices.
These storage devices include a tape storage system having only linear data access, Non-Volatile Flash or RAM drives with limited storage, and multiple hard disk drive RAID storage systems which are often non-portable and whose media cannot be easily removed or transported for direct use in other systems.
Also, the files stored on these storage devices have limited color correction, image processing or post production metadata integration.
However, these digital still cameras and camcorders have slow readout architectures (e.g., a DSLR may only shoot four (4) frames per second) and can only achieve video rate preview at low resolution (e.g., 640×480) or standard definition (e.g., VGA 640×480 at thirty (30) frames per second) using sub-sampling or windowing techniques.
These digital still cameras and camcorders compress the colorized images for storage; but the compressing process performed by these devices prevents access to the original full raw image pixel data for later processing, analysis or colorization.
This typically results in a reduction in image quality compared to the original image or a coded version of the raw data.
Also, due to their architectures, these single sensor cameras lack the ability to transmit the imager raw content over existing broadcast or network infrastructure cabling for remote monitoring, networking, recording or visualization.
These single sensor cameras cannot process captured signals with prerecorded content or broadcast format signals for live composition, switching, grading, mixing into virtual sets or adding graphic overlays based on extracted metadata or analytics.
These single sensor cameras also lack the ability to manage, control or record multi-sensor imagers, which may be remotely connected to a recording system.
While digital camera systems have been used to produce this type of content, these camera systems suffer from the same system limitations as the cameras described above.
These camera systems are large and bulky such that the camera systems cannot be placed very close together physically, as is required for short inter-ocular distances in 3D stereographic or for creating hemispherical views where cameras need to be placed as close together as possible from a common center point.
When shooting thru mirrors and beam splitters, rigs (i.e., a combination of digital cameras, optics and mounting platform) become more cumbersome and difficult to use in handheld shooting environments.
Finally, these camera systems lack a comprehensive set of image processing, visualization, positioning control, recording, playback, communications and display tools for use in such high-definition multi-camera systems.

Method used

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Embodiment Construction

[0025]As shown in FIGS. 1-12 for purposes of illustration, the present invention resides in a digital camera system that captures scalable resolution, bit-depth and frame rate raw or color processed images from one or more modular imaging modules at precise film or video rates. The present invention utilizes industry standard cabling infrastructure for transmitting either the raw sensor data or processed raw on the same or different links. The present invention provides a mechanism for timing synchronization of exposure and readout cycles from multiple imaging modules. The present invention also provides a unified software or operator interface to control the capture, processing and non-destructive visualization from one or more imaging modules. The present invention can optionally combine live imagery with previously stored imagery or computer generated virtual sets, while simultaneously recording the raw, broadcast format, or visualization processed imagery in its original or near...

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PUM

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Abstract

A digital camera system (20), as illustrated in FIG. 1, includes an optical assembly (22) to gather light (24) from a desired scene (26), a modular imaging subsystem (28) aligned with the optical assembly (22), and an image processing, recording and display subsystem (34).

Description

CROSS-REFERENCE TO RELATED APPLICATION(S)[0001]This application claims priority to and the benefit of U.S. Provisional Application Ser. No. 60 / 923,339, the entire content of which is incorporated herein by reference.FIELD OF THE INVENTION[0002]The present invention is related, in general, to a digital cinema camera system. More particularly, the present invention is related to a digital cinema camera system for recording, editing and visualizing images.BACKGROUND OF THE INVENTION[0003]For many years, film cameras were the only option for capturing cinema quality motion pictures. The time requirements and costs related to shooting and processing motion picture images on film stock and then transferring those images into a digital form have created a need for motion picture cameras that capture high definition or cinema resolution imagery directly in a digital form. The advent of Digital Cinemas, cost effective Stereo 3D Digital cinema projection systems and establishment of Digital C...

Claims

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Application Information

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Patent Type & Authority Applications(United States)
IPC IPC(8): H04N5/93H04N5/225H04N5/228H04N13/02H04N13/189H04N13/239H04N23/40
CPCH04N5/225H04N5/232H04N5/765H04N5/772H04N5/781G03B17/56H04N5/907H04N9/7921H04N9/804H04N13/0203H04N5/85H04N13/204H04N13/189H04N13/257H04N13/194H04N13/239H04N13/161H04N13/275H04N23/52H04N23/661H04N23/633H04N23/631H04N23/695H04N23/95H04N25/745H04N23/00H04N25/75
Inventor PRESLER, ARI M.
Owner SILICON IMAGING CORP
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